In what areas of programming is a knowledge of mathematics helpful?

For example, math logic, graph theory.

Everyone around tells me that math is necessary for programmer. I saw a lot of threads where people say that they used linear algebra and some other math, but no one described concrete cases when they used it.

I know that there are similar threads, but I couldn't see any description of such a case.

-
This should be community wiki. –  Earlz Dec 9 '09 at 19:49
As a wiki I think this is a perfectly acceptable question... –  Dave Swersky Dec 9 '09 at 19:52
Sergey, by not changing this into a Community-Wiki question, chances are that your question will be closed. –  Bart Kiers Dec 9 '09 at 20:10
At the risk of feeding the troll, I'll bite: You're right, your comment doesn't answer the question. But your statement that math is only "required" for "some specific areas" is dubious at best. Math is at the very foundation of computing -- certainly, every programmer depends on tools that were implemented with math knowledge. So it must be that your statement is that knowledge of math is not a prerequisite for programming. Narrowly defined, that may be true -- but that knowledge is so helpful in so many cases that I'd argue that it is a prerequisite for skillful programming. –  Daniel Pryden Dec 9 '09 at 20:26
Sounds like a duplicate: stackoverflow.com/questions/11743/useful-math-for-programmers –  gnovice Dec 9 '09 at 20:52

It's all matrix multiplication, vector spaces, affine spaces, projection, etc. Lots and lots of algebra.

For more information, here's the Wikipedia article on projection, along with the more specific case of 3D projection, with all of its various matrices. OpenGL, a common computer graphics library, is an example of applying affine matrix operations to transform and project objects onto a computer screen.

-
I've personally had to use Calculus in vector graphics in particular. –  Ben Lesh Dec 9 '09 at 19:58
Why not provide an example or two to drive home your answer? –  ChaosPandion Dec 9 '09 at 20:05
No point giving code for neat visualizations without being able to look at them, but you can look at someone else's nice code together with videos here: mndl.hu/hackpact –  mquander Dec 9 '09 at 20:14

I was using co-ordinate geometry to solve a problem of finding the visible part of a stack of windows, not exactly overlapping on one another.

There are many other situations, but this is the one that I got from the top of my head. Inherently all operations that we do is mathematics or at least depends on/related to mathematics.

Thats why its important to know mathematics to have a more clearer understanding of things :)

Infact in some cases a lot of math has gone into our common sense that we don't notice that we are using math to solve a particular problem, since we have been using it for so long!

Thanks

-

Given a list of locations with latitudes and longitudes, sort the list in order from closest to farthest from a specific position.

All applications that deal with money need math.

I can't think of a single app that I have written that didn't require math at some point.

-
How about pure API calls application? –  Dr. Xray Dec 9 '09 at 19:55
What kind of interesting application would be "pure API calls?" –  Ken Bloom Dec 9 '09 at 20:14

In graphic world you need a lot of transformations.
In cryptography you need geometry and number theory.
In AI, you need algebra.
And statistics in financial environments.
Computer theory needs math theory: actually almost all the founders are from Maths.

-

I wrote a parser compiler a few months back, and that's full of graph-theory. This was only designed to be slightly more powerful than regular expressions (in that multiple matches were allowed, and some other features were added), but even such a simple compiler requires loop detection, finite state automata, and tons more math.

-

Implementing the Advanced Encryption Standard (AES) algorithm required some basic understanding of finite field math. See act 4 of my blog post on it for details (code sample included).

-

I've used a lot of algebra when writing business apps.

Simple Examples

``````BMI = weight / (height * height);
compensation = 10 * hours * ((pratio * 2.3) + tratio);
``````
-
That's not algebra, that's little more than arithmetic. Algebra would be about calculating one or more unknown values from a set of equations. –  duffymo Dec 11 '09 at 10:56

As an engineer, I'm trying really hard to think of an instance when I did not need math. Same story when I was a grad student. Granted, I'm not a programmer, but I use computers a lot.

-

One time I was writing something for my Commodore 64 (I forget what, I must have been 6 years old) and I wanted to center some text horizontally on the screen.

I worked out the formula using a combination of math and trial-and-error; years later I would tackle such problems using actual algebra.

-
I don't mean to imply that this is the last time I used math in a program. I'm pretty sure I also used it sometime in 1983 to simulate a lunar lander. Details fuzzy. ;) –  Jason Orendorff Dec 9 '09 at 20:02

Drawing, moving, and guidance of missiles and guns and lasers and gravity bombs and whatnot in this little 2d video game I made: wordwarvi

Lots of uses sine/cosine, and their inverses, (via lookup tables... I'm old, ok?)

-

Any geo based site/app will need math. A simple example is "Show me all Bob's Pizzas within 10 miles of me" functionality on a website. You will need math to return lat/lons that occur within a 10 mile radius.

-

I wrote some hash functions for mapping airline codes and flight numbers with good efficiency into a fairly limited number of data slots.

I went through a fair number of primes before finding numbers that worked well with my data. Testing required some statistics and estimates of probabilities.

-

I think that a lot of programmers use more math than they think they do. It's just that it comes so intuitively to them that they don't even think about it. For instance, every time you write an if statement are you not using your Discrete Math knowledge?

-
Reminds me the book 'The Math Instinct...' which deals with instinctive math amazon.com/exec/obidos/tg/detail/-/1560256729/literatinet –  Liran Orevi Dec 9 '09 at 20:12

Games and simulations need lots of maths - fluid dynamics, in particular, for things like flames, fog and smoke.

-

A few years ago, I had a DSP project that had to compute a real radix-2 FFT of size N, in a given time. The vendor-supplied real radix-2 FFT wouldn't run in the allocated time, but their complex FFT of size N/2 would. It is easy to feed the real data into the complex FFT. Getting the answers out afterwards is not so easy: it is called post-weaving, or post-unweaving, or unweaving. Deriving the unweave equations from the FFT and complex number theory was not fun. Going from there to tightly-optimized DSP code was equally not fun.

Naturally, the signal I was measuring did not match the FFT sample size, which causes artifacts. The standard fix is to apply a Hanning window. This causes other artifacts. As part of understanding (and testing) that code, I had to understand the artifacts caused by the Hanning window, so I could interpret the results and decide whether the code was working or not.

-

As an e-commerce developer, I have to use math every day for programming. At the very least, basic algebra.

There are other apps I've had to write for vector based image generation that require a strong knowledge of Geometry, Calculus and Trigonometry.

Estimating load potential of an application...

Yep, if someone is no good with math, they're probably not a very good programmer.

-

I've used tons of math in various projects, including:

• Graph theory for dealing with dependencies in large systems (e.g. a Makefile is a kind of directed graph)
• Statistics and linear regression in profiling performance bottlenecks
• Coordinate transformations in geospatial applications
• In scientific computing, project requirements are often stated in algebraic form, especially for computationally intensive code

And that's just off the top of my head.

And of course, anything involving "pure" computer science (algorithms, computational complexity, lambda calculus) tends to look more and more like math the deeper you go.

-

I primarily develop applications that perform financial calculations and projections. Can't avoid math.

-

In answering this image-comparison-algorithm question, I drew on lots of knowledge of math, some of it from other answers and web searches (where I had to apply my own knowledge to filter the information), and some from my own engineering training and lengthy programming background.

-

-Graphics (matrices, translations, shaders, integral approximations, curves, etc, etc,...infinite dots)
-Algorithm Complexity calculations (specially in line of business' applications)
-Pointer Arithmetics
-Cryptographic under field arithmetics etc.
-GIS (triangles, squares algorithms like delone, bounding boxes, and many many etc)
-Performance monitor counters and the functions they describe
-Functional Programming (simply that, not saying more :))
-......

-

I used Combinatorials to stuff 20 bits of data into 14 bits of space.

-

I'm working on a rate calculation program for an insurance database now. There's some fairly involved statistical modeling involved. Most of the heavy lifting has already been done for me, but it still helps to have an understanding of the underlying math in order to accurately translate the formulas into code.

-

This is primarily a question whose answer will depend on the problem domain. Some problems require oodles of math and some require only addition and subtraction. Right now, I have a pet project which might require graph theory, not for the math so much as to get the basic vocabulary and concepts in my head.

If you're doing flight simulations and anything 3D, say hello to quaternions! If you're doing electrical engineering, you will be using trig and complex numbers. If you're doing a mortgage calculator, you will be doing discrete math. If you're doing an optimization problem, where you attempt to get the most profits from your widget factory, you will be doing what is called linear programming. If you are doing some operations involving, say, network addresses, welcome to the kind of bit-focused math that comes along with it. And that's just for the high-level languages.

If you are delving into highly-optimized data structures and implementing them yourself, you will probably do more math than if you were just grabbing a library.

-

In machine learning: we use Bayesian (and other probabilistic) models all the time, and we use quadratic programming in the form of Support Vector Machines, not to mention all kinds of mathematical transformations for the various kernel functions. Calculus (derivatives) factors into perceptron learning. Not to mention a whole theory of determining the accuracy of a machine learning classifier.

In artifical intelligence: constraint satisfaction, and logic weigh very heavily.

-

I develop mostly applications that have to do with decision analysis and financial forecasting. In that frame, math is a key component of most of my development work. In no particular order, on top of my head:

• Run simulation of the possible outcomes of a project, generate cumulative distributions and analyze the distribution (probability, statistics, simulation)
• Compute the optimal allocation of supply to demand over time on a market (algebra, optimization)
• Model the prescription decision physicians make, based on an attribute model and the results of a survey, to determine adoption of new products (algebra, micro-economics)
• Model the evolution of patients through a disease (graphs, markov chains)

In general, I am using a small subset of what I learnt in math / quantitative methods. Usually straightforward algebra, with the occasional probability usage, is sufficient - especially if your application is mostly about record-handling...
On the other hand, I found that knowing a wide array of mathematical techniques or ideas help you think better about problems, see connections, similarities and dissimilarities, or know better what to look for.

-

Part of being a good programmer is being familiar with the domain in which you are programming. If you are working on software for Fidelity Mutual, you probably would need to know engineering economics. If you are developing software for Gallup, you probably need to know statistics. LucasArts... probably Linear Algebra. NASA... Differential Equations.

The thing about software engineering is you are almost always expected to wear many hats.

-

When solving some depth-first searching problems (e.g., sudoku puzzles) I've leveraged Knuth's Dancing Links algorithm, which falls under the graph theory and logical deduction categories.

-

Statistics comes up at times where I work, e.g. what % of site visitors are using IE7 or Firefox, etc. There can also be times where I have to take raw data and compute sums, averages or other aggregate functions.

Boolean Algebra is commonly used in conditionals that I'd think is a concrete case.

-

Doppler shift is logarithmic. Promoting a mathematics education or textbook. Or any leverage, ratio or advanced project. And logic has other definition. Where market industry standard and leader team programmer with designer. I'd choose team programmer with mathematician.

-

More or less anything having to do with finding the best layout, optimization, or object relationships is graph theory. You may not immediately think of it as such, but regardless - you're using math!

An explicit example: I wrote a node-based shader editor and optimizer, which took a set of linked nodes and converted them into shader code. Finding the correct order to output the code in such that all inputs for a certain node were available before that node needed them involved graph theory.

And like others have said, anything having to do with graphics implicitly requires knowledge of linear algebra, coordinate spaces transformations, and plenty of other subtopics of mathematics. Take a look at any recent graphics whitepaper, especially those involving lighting. Integrals? Infinite series?! Graph theory? Node traversal optimization? Yep, all of these are commonly used in graphics.

Also note that just because you don't realize that you're using some sort of mathematics when you're writing or designing software, doesn't mean that you aren't, and actually understanding the mathematics behind how and why algorithms and data structures work the way they do can often help you find elegant solutions to non-trivial problems.

-